Electric discharge apparatus



2 sheets-snail INVENTQR DonahRfZu/k D. P. FAULK ELECTRIC DISCHARGE APPARATUS Filed Jan. 16. 1941 WEN Nov. 3, 1942.

WITNESSES:

A1TORNEY Nov. 3, 1942. D. P. FAULK ELECTRIC DISCHARGE APPARATUS 2 Sheets-Sheet 2 Filed Jan. 16, 1941 INVENTOR Dona/d P/d/k.

BY 2 ATTORNEY WITNESSES! Patented Nov. 3, 1942 ELECTRIC DISCHARGE APPARATUS Donald P. Faulk, Pittsburgh, Pa., assignor to Westinghouse Electric & Manufacturing Company, East Pittsburgh, Pa., a corporation of Pennsylvania Application January 16, 1941, Serial No. 374,66!

25 Claims.

My invention relates to electric discharge apparatus and has particular relation to welding apparatus.

In welding apparatus constructed and operated in accordance with the teachings of the prior art, of which I am aware, current is supplied to the primary of the welding transformer through electric discharge valves. The primary current is increased gradually in a time interval of the order of 20 or 30 half-periods of the source until it reaches a predetermined value and then is interrupted. As the flux, which was built up in the transformer by the primary current, decays, a potential impulse is induced in the secondary and welding current flows through the secondary and the material to be welded. A mechanical contactor serves to interrupt the primary current. The contactor is provided with a plurality of disconnecting elements which are operable in succession to open short-circuits across a substantial resistance in the primary circuit. When the contactor opens the resistance in the primary circuit is progressively increased. The rate of decay of the flux in the transformer is fixed by the time interval during which the contactor operates.

In practice, difllculty has been experienced with the prior art apparatus. Because of the high reactive impedance in the contactor circuit, a

substantial arc is produced between the contacts during interruption. While the apparatus is in use, the contacts open and close repeatedly at short intervals and the arcing soon deteriorates the contactor. A more important disadvantage of the prior art apparatus arises from the fact that the rate of decay of the flux in the transformer is-flxed by the rate at which resistance is introduced in the primary circuit and is comparatively small. The range over .which the magnitude and duration of the welding current is adjustable is, therefore, narrow and where large current impulses of short duration are required to properly weld a material the prior art apparatus is unsatisfactory.

It is, accordingly, an object of my invention to provide a welding system in which the rate of decay of flux in the welding transformer which induces the welding current shall be large.

Another object of my invention is to provide a weld ng system in which the rate of decay of flux in the welding transformer which induces the welding current in the secondary shall be adjustable over a wide range.

A further object of my invention is to provide a welding system in which no deleterious arcing shall occur on the opening of the primary circuit of the welding transformer while substantial current is flowing through the primary.

An ancillary object of my invention is to provide a novel control circuit for an electric discharge valve.

Another ancillary object of my invention is to provide an electric discharge valve circuit for controlling the current flow through a highly reactive impedance.

More specifically stated, it is an object of my invention to eliminate the interrupting contactor and its attendant disadvantages from a welding system in which the weld is produced by gradually increasing the current flowing through the primary of a welding transformer and opening the primary circuit when the current reaches a predetermined value.

In accordance with my invention, the current flowing through the primary of the welding transformer is interrupted by impressing a blocking potential across the electric discharge valves through which the current is supplied. The blocking potential is impressed through an auxiliary electric discharge valve and thus an interrupting contactor is avoided. Once the current flow is interrupted, another electric discharge valve, preferably an ignitron, connected in parallel with the primary is rendered conductive and the primary current arising from the decay of flux in the transformer flows through the valve. The conductivity of the auxiliary valve and the parallel valve is controlled from the primary. The latter is connected in the control circuit of the valves in such manner that the reversal of the polarity of the primary potential which occurs when the current flow to the primary is being interrupted renders the valves conductive. The parallel valve, particularly, if it is'an ignitron connected acrossthe terminals of the primary through a substantialresistance, in J efiect, constitutes a shunt circuit across the primary, and the rate of decay of flux in the welding transformer is high. To regulate the rate of decay, the resistance connected in series withthe parallel valve in the shunt circuit may be varied. The rate of decay of the flux which produces the current flow through the shunt circuit determines the rate of decay of the flux which produces the current flow through the material to be welded.

The novel features that I consider characteristic -of my invention are set forth with particularity in the appended-claims. The invention itself, however, both as to its organization and its method of operation, together with further objects and advantages thereof, will best be understood by reference to the following description and to the drawings; in which:

Figure 1 is a diagrammatic view showing a preferred embodiment of my invention;

Fig. 2 is a. graph showing the relationship between the voltages in the embodiment of my invention shown in Fig. 1;

Fig. 3 is a reproduction of an oscillograph produced with apparatus in accordance with my invention: and

Fig. 4 is a reproduction of a corresponding osciliograph for prior art apparatus.

The apparatus shown in Fig. 1 comprises a polyphase source 5 from which a supply transformer I is energized. The secondary 9 of the transformer is connected in zig-zag and electric discharge valves II, I3 and I5, preferably ignitrons, are connected between the external terminals of each of the windings of the transformer and the primary I1 of a welding transformer I9. The electric discharge valves II to I5 need not necessarily be ignitrons. They may be mercury pool devices of other types and in the event that the primary current is relatively small,

they may also be discharge devices of the hotv cathode type.

The magnitude to which the current flowing through the primary of the welding transformer I9 rises is controlled by a current relay 2|. When the current reaches the desired value, the relay 2| operates, actuating an auxiliary relay 23 which opens the anode circuits of the igniter valves 25, 21 and 29 of the supply ignitrons II, I3 and I5 respectively. The primary current is not interrupted when the firing circuits of the supply ignitrons open. The opening of the circuits merely prevents the ignitrons which happen to be non-conductive when it occurs from becoming conductive in their turn as their anode potentials exceed the anode potentials impressed on the other ignitrons. The ignitron which is conductive when the firing circuits are opened remains conductive under the influence of the back potential impressed from the welding transi'ormer by reason of its high reactance.

The current fiow through the latter ignitron is interrupted by a blocking capacitor 3|. The capacitor is initially charged to a potential such as to oppose the current flow through the supply ignitrons through a thyratron 33 (or a high vacuum valve) and is connected across the ignitrons II to I5 through an auxiliary valve 35, preferably an ignitron. Firing current is supplied to the auxiliary ignitron 35 through a thyratron 31 in the control circuit of which a biasing potential 39 is interposed in series with the algebraic sum of the primary potential of the welding transformer I9 and the potential impressed through whatever supply ignitron happens to be conductive. When the firing circuits of the sup ply ignitrons are opened, the potential impressed across the ignitron which is last conducting current decreases and the potential across the primary, which is originally negative, increases (becomes progressively less negative and then positive) correspondingly. Eventually, the sum of the potentials attains such a value as to counteract the biasing potential in the control circuit of the thyratron 31 from which the auxiliary ignitron 35 is fired. The ignitron becomes conductive connecting" the blocking capacitor 3| across the conductive supply ignitron, and rendering the latter non-conductive.

When the current flow from the supply transformer I has been interrupted, a shunting discharge valve 4|, which is also preferably an ignitron, is rendered conductive by the further increase of the potential across the primary. The current arisingfrom the decay of flux in the welding transformer I9 discharges through the shunting ignitron and through a variable resistor 43 in series therewith. The resistor may be set at a proper value to correspond to the desired rate of decay.

With the apparatus in the condition illustrated in the drawings, a welding operation may be initiated by closing, a manual controller 45 such as a foot switch, is operated. The lower movable contactor 41 of the controller closes completing an energizing circuit through the exciting coil 49 of a fiuid pressure valve 5|. The valve operates, permitting a fluid under pressure to flow into a piston chamber 53 and to move a piston 55. The piston carries the movable welding electrode 51 and when it is actuated the movable electrode is urged into engagement with the material 59 to be welded which is held in engagement with the fixed welding electrode 6|. The fluid continues to flow, increasing the pressure on the piston 55 and compressing another piston 63 in an auxiliary chamber 95 in communication with the electrode piston chamber 53. The latter piston moves against the action of a spring 61 and closes the movable contactor 99 of a pressure switch II when the pressure on the movable welding electrode 51 has reached the desired magnitude.

The exciting coil 13 of the auxiliary relay 23 is now energized in a circuit extending from the upper terminal of the secondary 15 of an auxiliary transformer 11, through the coil 13 of the relay, a normally closed back contact 19 of another auxiliary relay 8|, the contact 69 of the back pressure switch II to the lower terminal of the secondary. The power relay 23 is actuated and its movable contactors 83, and 81 close completing the firing circuits for the supply ignitrons II, I3 and I5, respectively. The firing circuits for ignitron extends from the terminal of one of the windings 99 from which the ignitron is supplied through the corresponding contactors 93, the anode 9| and cathode 93 of the firing valve 25, a resistor 95, the igniter 91 and cathode 99 of the ignitron, the primary I1 to the neutral conductor ml. The firing circuits for the other supply ignitrons may be correspondingly traced.

As the potential of each of the phases of the source 5 exceeds the potential of the other phases, firing current flows through the corresponding firing circuits and the corresponding supply ignitrons are rendered conductive. Current flows through the primary I1 and through the energizing coil I93 of the current relay 2|. Because of the high rea'ctance of the welding transformer I9, the current through the primary I1 rises gradually. When the current reaches a predetermined value, the current relay 2| is actuated and its contactor I95 closes. A circuit is now completed which extends from the upper terminal of the secondary 15 of the auxiliary transformer 11 through the exciting coil I91 of the auxiliary relay 9|, the upper contact I99 of the manual controller 45, the contact I95 of the current relay 9| is actuated and its front contact I is closed while its back contacts 19 and 3 are opened.

With the opening of the back contact 19, the circuit for the exciting coil 13 of the relay 23 controlling the firing of the supply ignitrons II, I3 and I is opened and the relay drops out, opening the firing circuits. One of the supply ignitrons is conductiveand the other are non-conductive when the firing circuits are opened. As the operation progresses, the non-conductive ignitrons do not become conductive in their turn because their firing circuits are open. The conductive ignitron continues to carry current as the potential of the phase from which it is supplied decreases by reason of the reactive impedance in its anode-cathode circuit. As the phase potential decreases, the potential across the primary I1 of the welding transformer increases and the net potential impressed in the anode circuit of the still conducting ignitron remains positive. The conducting ignitron is rendered non-conductive by impressing the potential of the blocking capacitor 3| in its anode circuit. As an initial step in the sequence of operation which lead to this even-t, the charging circuit for the capacitor 3| is opened when the back contact II3 of the relay 9! is opened.

The control circuit for the thyratron 31 through which the auxiliary ignitron 35 is fired extends from its control electrodes I I5 through a grid resistor II1 to the biasing potential 39, thence the parallel network consisting of the primary I1 of the welding transformer I9 on the one hand, and the windings of supply secondary 9 corresponding to the conductive supply ignitron (I I, I3 or I5) on the other hand; and finally through the cathode II9 and the igniter I2I of the auxiliary ignitron 35 to the cathode I23 of the thyratron 31. As the potential across the primary I1 of the welding transformer I9 rises after the ignitron control relay 23 opens, the bias potential 39 in the control circuit of the firing thyratron 31 is counteracted until the critical potential of the thyratron is exceeded and the ignitron 35 becomes conductive connecting the capacitor across the conductive supply ignitron. The capacitor 31 is initially charged so that it positive plate is connected to the anode I25 of the auxiliary ignitron 35 and its negative plate to the neutral conductor IDI of the supply transformer. The cathode II9 of the auxiliary ignitron is connected to the common cathode conductor I21 of the supply ignitrons. The charged capacitor is thus connected across the conductive supply ignitron through one or the other of the windings of the supply secondary 9 in such mannerv that it opposes the current flow through the latter ignitron and renders it non-conductive. The current relay 2| is now 'deenergized and drops out but the circuit through the exciting coil I01 of the auxiliary relay 8| is maintained closedthrough the closed front contact I of the relay.

The potential from the primary I1 of the welding transformer I9 is also impressed between the anode I29 and the cathode I3I of the shunting ignitron 4| and between the anode I33 and the cathode I35 of the firing thyratron I36 for the latter (connected to function as an ordinary rectifier) through the variable resistor 43. After the last supply ignitron becomes non-conductive, firing current is supplied to the shunting ignitron H and it is rendered conductive. The current arising from the decay of the flux in the welding transformer I9 is now discharged through the ignitron 4I. The rate of decay may be adjusted by setting the variable resistor 43. By reason of the decay of fluxin the welding transformer, welding current is induced in its secondary I31 and the material 59 is welded.

The operation may be repeated by releasin the manual controller 45 and reclosing it. When the controller is released, the holding circuit for the auxiliary relay 8| is opened at the controller contact I99 and the relay drops out, resetting the apparatus.

The variation of the potentials impressed across the control circuit of the thyratron 31 through which the firing current for the auxiliary ignitron 35 is transmitted is illustrated in Figure 2. In the graph shown in this figure, potential is plotted vertically and then horizontally. The sine curves I39 which are shown partly in full lines and partly in broken lines represent the potential derived from the secondary 9 of the supply transformer 1. The full line portions I4I of the curves represent the intervals during which the respective supply ignitrons (I I, I3 and I5) are successively conductive. The potential impressed across the primary I1 of the welding transformer I9 through the supply ignitrons is represented by the full line curve formed by combining the full line portions I of the sine curves since the potential drop across a conductive ignitron is relatively small.

Assume that at some instant represented by the point T, the current relay operates and the firing circuits for the supply ignitrons II, I3 and I5 is opened. Only one of the ignitrons is then conductive and the potential which is impressed across the ignitron from the source decreases, as illustrated by the full line branch I43 of the sine curve on the extreme right of the graph. The potential across th primary I1 of the welding transformer I9'is represented by the full line curve I45 in the lower quadrant of the graph. The potential remains substantially constant until the firing circuits for the supply ignitrons are opened. At this point, the potential from the source decreases and the flux in the welding transformer tends to decay. The decay in flux causes an increase in the potential across the primary as illustrated by the rising branch I41 of curve I45 0n the right. The net potential which is impressed in the control circuit of the thyratron 31 associated with the auxiliary ignitron 35 is represented by the algebraic sum of V the ordinates of the curves HI and I 45. When the sum plus the biasing potential 39 is greater than the critical potential, the thyratron 31 is rendered conductive and the auxiliary ignitron 35 is fired.

Fig. 3 is a reproduction of an oscillogram of the current flow through the primary I1 of the welding transformer I9. Current is plotted vertically and time horizontally. The rising wavy branch I49 of the graph corresponds to the increasing current in the primary of the welding transformer. At the instant T, the firing circuits for the supply ignitrons II, I3 and I5 are opened. Thereafter, the flux in the transformer decays and the resulting current is absorbed in the shunting ignitron M. The full line loop I5I on the extreme right represents the current flow for one setting of the resistor 43. If the magnitude of the resistance is increased, the current flow may be represented by a curve corresponding to the broken line loop I53.

A corresponding oscillogram for a prior art welder in which resistance is gradually connected in series with the primary of the welding transformer by opening a mechanical contactor, is reproduced in Fig. 4. The wavy loop I on the right extending from the wavy branch I51 of the curve represents the current flow in the primary of the welding transformer as the contactor is being opened. It is seen that in a system in accordance with my invention, the rate of decay of the flux is considerably greater than in the prior art apparatus. Moreover, in the practice of my invention, the rate may be varied over an appreciable range. For the welding of many materials, the possibility of varying the rate of decay is an important feature as it enables the operator to correlate the properties of the material to be welded and the magnitude and timing of the welding current precisely.

In a system in accordance with my invention which has actually been constructed and tested, the supply ignitrons II, I3 and I5 are Westinghouse WL-656 tubes and they are energized from a 220 volt source through a transformer across the secondary windings of which the potential is 130 volts. The firing thyratrons 25, 21 and 29 for the supply ignitrons are Westinghouse WL-632 tubes. The blocking capacitor 3| has a capacity of 500 mi. It is charged from a 440 volt (R. M. S.) source through a 100 ohm resistor I6I and a Westinghouse KU-676 thyratron 33. The auxiliary ignitron and the shunting ignitron 4| are Westinghouse WL-651 tubes. The corresponding firing thyratrons 31 and I36 are Westinghouse WL-632 tubes. The resistor l3 connected in series with the shunting ignitron is 2 to 5 ohms. The current limiting resistors I63 and IE5 in the firing thyratron circuits for the auxiliary ignitron and the shunt ignitron are each 10 ohms. In the control circuit of the thyratron, through which the auxiliary ignitron is fired, there is a biasing potential 39 of volts and a .5 meghom grid resistor III. The control electrode I61 of the thyratron I35 through which the shunting ignitron ll is fired, is connerted to its anode I33 through a .5 megohm resistor I69.

Although I have shown and described certain specific embodiments of my invention, I am fully aware that many modifications thereof are possible. My invention, therefore, is not to be restricted except insofar as is necessitated by the prior art and by the spirit of the appended claims.

I claim as my invention:

1. In combination, a reactor, an electric discharge device having an anode and cathode in circuit with said reactor and a control electrode, means for impressing a potential across said reactor for supplying current thereto, means for varying said impressed potential, and a control circuit for said device extending from said control electrode to said cathode and including said reactor for controlling the conductivity of said device in response to the variation of the poten-- tial across said reactor as said impressed potental is varied.

2. In combination, a reactor, an electric discharge device having an anode and cathode in circuit with said reactor and a control electrode, means for impressing a potential across said rea tor for supplying current thereto, means for decreasing said impressed potential, and a control circuit for said device extending from said control electrode to said cathode and including a source of biasing potential tending to maintain said device non-conductive, and said reactor connected so that the variation in potential across said reactor as said impressed potential is decreased counteracts said biasing potential to render said device conductive.

3. In combination, a reactor, an electric discharge device having a pair oi principal electrodes in circuit with said reactor and a control electrode, means for impressing a potential across said reactor for supplying current thereto. means for varying said impressedpotential, a control circuit extending between said control electrode and one of said principal electrodes and including said reactor for controlling the conductivity of said device in response to the variation in the polarity of the potential across said reactor as said impressed potential is varied.

4. For use in supplying a reactive load from a source of periodically pulsating potential, the combination comprising electric discharge valve means of the are like type connected between said source and said reactor for impressing a potential across said reactor to supply current therethrou'gh, a capacitor and a normally nonconductive electric discharge device connected in circuit with said valve means, means for varying the potential impressed across said reactor and control means for said device comprising a control circuit including said reactor so connected that th variation in the potential across said reactor as said impressed potential is varied is effective to render said device conductive thereby to connect said capacitor in circuit with said valve means.

5. For use in supplying a reactive load from a source of periodically pulsating potential, the combination comprising electric discharge valve means of the are like type connected between said source and said reactor for impressing a potential across said reactor to supply current therethrough, a capacitor and a normally nonconductive electric discharge device connected in circuit with said valve means, means for main taining said capacitor charged to a potential of a polarity such that the current flow through said valve means would be opposed if said capacitor were connected in circuit with said valve means by rendering said device conductive. means for varying the potential impressed across said reactor and control means for said device comprising a control circuit including said reactor so connected that the variation in the polarity of the potential across said reactor as said impressed potential is varied is effective to render said device conductive thereby to connect said capacitor in circuit with said valve means.

6. For use in supplying a reactive load from a source of periodically pulsating potential, the combination comprising electric discharge valve means of the are like type connected between said source and said load for impressing a potential across said reactor to supply current therethrough, a capacitor and a normally non-conductive electric discharge device connected in circuit with said valve means, means for controlling the conductivity of said valve means for varying the potential impressed across said load and means responsive to the variation in the potential across said load as said impressed potential is varied for rendering said device conductive thereby to connect said capacitor in circuit with said valve means.

7. For use in supplying a reactive load from a source of periodically pulsating potential, the combination comprising electric discharge valve means of the are like type connected between said source and said load for impressing a potential across said reactor to supply current therethrough, a capacitor and a normally non-conductive electric discharge device connected in circuit with said valve means, means for varying the potential impressed across said load and means. responsive to the variation 01' the polarity of the potential across said load as said impressed potential is varied for rendering said device conductive thereby to connect said capacitor in circuit with said valve means.

8. For use in supplying a reactive load from a source 01' polyphase potential, the combination comprising electric discharge valve means of the arc like type connected between said source and said load for impressing apotential across said reactor to supp y current therethrough, a capacitor and a, normally non-conductive electric discharge device connected in circuit with said valve means, means for interrupting the connections between certain of the phase terminals of said source and said load to vary the potential impressed across said load and means responsive to the variation in the potential across said load as said impressed potential is varied for rendering said device conductive thereby to connect said capacitor in circuit with said valve means.

9. For use in supplying a reactive load from a source 'of periodically pulsating potential, the combination comprising electric discharge valve means of the are like type connected between said source and said load for impressing a potential across said reactor to supply current therethrough, a capacitor and'a normally open circuit-closing-and-opening means connected in circuit with said valve means, means for varying the potential impressed acrosssaid load and means responsive to the variation in the polarity of the potential across said load as said impressed potential is varied for closing said circuit-closingand-opening means thereby to connect said capacitor in circuit with said valve means.

10. For use in supplying a reactive load from a source of polyphase potential, the combination comprising electric discharge valve means of the are like type connected between each phase of said source and said load, means for rendering the valve means connected to the phases of said source conductive in succession for impressing a potential across said reactor to supply current therethrough, a capacitor and a normally nonconductive electric discharge device connected in circuit with said valve means, means for pre-.

venting the valve means connected to certain of the phases said source from becoming conductive in their turn to vary the potential impressed across said load and means responsive to the variation in the potential across said load as said impressed potential is varied for rendering said device conductive thereby to connect said capacitor in circuit with said valve means.

11. For use in supplying a reactive load from a source of polyphase potential, the combination comprising electric discharge valve means of the arc like type connected between each phase of said source and said load, means for rendering the valve means connected to the phases of said source conductive in succession for impressing a potential across said reactor to supply current therethrough, a capacitor and a normally nonconductive electric discharge device connected in circuit with said valve means, means for preventing the valve means connected to all but one of the phases of said source from becoming conductive in their turn to vary the potential impressed across said load and means responsive to the variation in the potential across said load as said impressed potential'is varied for rendering said device conductive thereby to connect said capacitor in circuit with said valve means.

12. For use in supplying a reactive load from a source of polyphase potential, the combination comprising electric discharge valve means 01 the are like type connected between each phase or said source and said load, means for rendering the valve means connected to the phases of said source conductive in succession for impressing a potential across said reactor to supply current therethrough, a capacitor and a-normally nonconductive electric discharge device connected in circuit with said valve means, means for preventing the valve means connected to the phases of said source from becoming conductive in their turn, once they are rendered non-conductive, to vary the potential impressed across said load and means responsive to the variation in the potential across said load as said impressed potential is varied for rendering said device conductive thereby to connect said capacitor in circuit with said valve means.

13. For use in supplying a reactive load from a source of polyphase potential, the combination comprising electric discharge valve means of the are like type connected between each phase of 'turn once they are rendered non-conductive to vary the potential impressed across said load and means responsive-to the variation in the potential across said load as said impressed potential is varied for rendering said device conductive thereby to connect said capacitor in circuit with said valve means.

14. For use in welding a material from a source comprising a work circuit including said material, reactive means in inductive relationship with said work circuit, means for supplying current from said source through said reactive means, means for interrupting the supply of current from said source through said reactive means and electric discharge valve means in circuit with said reactive means for conducting the current produced by the decay of flux in said reactive means when the current flow therethrough is interrupted.

15. For use in welding a material from a source comprising a work circuit including said material, reactive means in inductive relationship with said work circuit, means for supplying current from said source through said reactive means, means for interrupting the supply of current from said source through said reactive means, electric discharge valve means in circuit with said reactive means for conducting the current produced by the decay of flux in said reactive means when the current flow therethrough is interrupted, and adjustable means in circuit with said valve means for determining the rate of decay of said flux.

16. For use in welding a material from a source comprising a work circuit including said material, reactive means in inductive relationship with said work circuit, means for supplying current from said source through said reactive means, means for interrupting the supply of current from said source through said reactive means, electric discharge valve means in circuit with said reactive means for conducting the current produced by the decay of flux in said reactive means when the current ilow therethrough is interrupted, and variable impedance means in circuit with said valve means for adjusting the rate of decay of said flux.

1'7. For use in welding a material from a source comprising a work circuit including said material, reactive means in inductive relationship with said work circuit, means for supplying current from said source through said reactive means, means responsive to the current flow through said reactive means for interrupting the supply of current from said source through said, reactive means and electric discharge valve means in circuit with said reactive means for conducting the current produced by the decay of flux in said reactive means when the current flow therethrough is interrupted.

18. For use in welding a material from a source comprising a welding transformer having a primary and a secondary, said secondary being in circuit with said material, means for supplying current from said source through said primary, means for interrupting the supply of current from said source through said primary and electric discharge valve means in circuit with said primary for conducting the current produced by the decay or flux in said transformer when the current flow therethrough is interrupted.

19. In combination, a reactor, an electric discharge device having a pair of principal electrodes in circuit with said reactor and a control electrode, means for impressing a potential across said reactor for supplying current thereto, means for decreasing said impressed potential to effect a change in polarity of the potential across said reactor, a control circuit for said device extending between said control electrode and one of said principal electrodes and including a source of biasing potential tending to maintain said device non-conductive, said control circuit also including said reactor so connected that the potential across said reactor tends to counteract said biasing potential to render said device conductive when said change in polarity is effected.

20. For use in supplying a reactive load from a source of potential, the combination comprising electric discharge valve means of the arc-like type connected between said source and said reactor for impressing a potential across said reactor to supply current therethrough, a capacitor and a normally non-conductive electric discharge device connected in circuit with said valve means, means for varying the potential impressed across said reactor to efiect a change in the polarity of the potential across said reactor, and control means for said device comprising a control circuit including said reactor and means tending to prevent said device from being rendered conductive, said reactor being so connected that the potential thereacross counteracts said preventive means and effects conductivity of said device when said change in polarity is effected.

21. For use in supplying a reactive load from a source of potential, the combination comprising electric discharge valve means of the arclike type connected between said source and said reactor for impressing a potential across said reactor to supply current therethrough, a capacitor and a normally non-conductive electric discharge device connected in circuit with said valve means, means for controlling the conductivity of said valve means for varying the potential impressed across said load and thereby effect a change in the polarity of the potential across said load, and means responsive to the variation in the polarity of the potential across said load as said impressed potential is varied for rendering said device conductive thereby to connect said capacitor in circuit with said valve means.

22. For use in supplying energy to a work circuit from a source oi. current, the combination comprising reactive means in inductive relationship with said work circuit, means ior supplying current from said source through said reactive means, means for interrupting the supply of current from said source through said reactive means and electric discharge valve means in circuit with said reactive means for conducting the current produced by the decay of iiux in said reactive means when the current flow therethrough is interrupted.

23. For use in supplying energy to a work circuit from a source of current, the combination comprising reactive means in inductive relationship with said work circuit, means for supplying current from said source through said reactive means, electric discharge valve means in circuit with said reactive means for conducting the current produced by the decay of flux in said reactive means when the current flow therethrough is interrupted, and variable impedance means in circuit with said valve means for adjusting the rate of decay of said flux.

24. For use in supplying energy to a, work circuit from a source of current, the combination comprising reactive means in inductive relationship with said work circuit, means for supplying current from said source through said reactive means, means responsive to the current flow through said reactive means for interrupting the supply of current from said source through said reactive means and electric discharge valve means in circuit with said reactive means for conducting the current produced by the decay of flux in said reactive means when the current flow therethrough is interrupted.

25. For use in supplying energy to a work circuit from a source of current, the combination comprising a transformer having a primary and a secondary, said secondary being in said work circuit, means for supplying current from said source through said primary, means for interrupting the supply of current from said source through said primary and electric discharge valve means in circuit with said primary for conducting the current produced by the decay of flux in said transformer when the current flow therethrough is interrupted.

DONALD P. FAULK.

Disclaimer 2,300,538.D0nald P. Faulk, Pittsburgh, Pa. ELECTRIC DISCHARGE APPARATUS. Patent dated Nov. 3, 1942. Dlsclaimer filed Nov. 12, 1947, by the assignee, Westinghouse Electric Corporation, formerly Westinghouse Electric & Manufacturing Company. Hereby enters this disclaimer to claims 1 and 3 of said specification.

[Oflicial Gazette December 80, 1947.]

Disclaimer 2,300,538.D0nald P. Faulk, Pittsburgh, Pa. ELECTRIC DISCHARGE APPARATUS. Patent dated Nov. 3, 1942. Disclaimer filed Nov. 12, 1947, by the assignee, Westinghouse Electric Corporation, formerly Westinghouse Electric & Manufacturing Company. Hereby enters this disclaimer to claims 1 and 3 of said specification.

[Ofiicial Gazette December 30, 1947.] 

